4.4BSD/usr/src/share/zoneinfo/zic.c
/*-
* Copyright (c) 1991, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Arthur David Olson of the National Cancer Institute.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#ifndef lint
static char sccsid[] = "@(#)zic.c 8.1 (Berkeley) 7/19/93";
#endif /* not lint */
#ifdef notdef
static char elsieid[] = "@(#)zic.c 4.12";
#endif
#include <sys/types.h>
#include <sys/cdefs.h>
#include <sys/stat.h>
#include <time.h>
#include <tzfile.h>
#include <stdio.h>
#include <ctype.h>
#include <string.h>
#include <stdlib.h>
#ifndef TRUE
#define TRUE 1
#define FALSE 0
#endif /* !defined TRUE */
struct rule {
const char * r_filename;
int r_linenum;
const char * r_name;
int r_loyear; /* for example, 1986 */
int r_hiyear; /* for example, 1986 */
const char * r_yrtype;
int r_month; /* 0..11 */
int r_dycode; /* see below */
int r_dayofmonth;
int r_wday;
long r_tod; /* time from midnight */
int r_todisstd; /* above is standard time if TRUE */
/* or wall clock time if FALSE */
long r_stdoff; /* offset from standard time */
const char * r_abbrvar; /* variable part of abbreviation */
int r_todo; /* a rule to do (used in outzone) */
time_t r_temp; /* used in outzone */
};
/*
** r_dycode r_dayofmonth r_wday
*/
#define DC_DOM 0 /* 1..31 */ /* unused */
#define DC_DOWGEQ 1 /* 1..31 */ /* 0..6 (Sun..Sat) */
#define DC_DOWLEQ 2 /* 1..31 */ /* 0..6 (Sun..Sat) */
struct zone {
const char * z_filename;
int z_linenum;
const char * z_name;
long z_gmtoff;
const char * z_rule;
const char * z_format;
long z_stdoff;
struct rule * z_rules;
int z_nrules;
struct rule z_untilrule;
time_t z_untiltime;
};
extern char * icatalloc __P((char * old, const char * new));
extern char * icpyalloc __P((const char * string));
extern void ifree __P((char * p));
extern char * imalloc __P((int n));
extern char * irealloc __P((char * old, int n));
extern int link __P((const char * fromname, const char * toname));
extern char * optarg;
extern int optind;
extern void perror __P((const char * string));
extern char * scheck __P((const char * string, const char * format));
static void addtt __P((time_t starttime, int type));
static int addtype
__P((long gmtoff, const char * abbr, int isdst,
int ttisstd));
static void addleap __P((time_t t, int positive, int rolling));
static void adjleap __P((void));
static void associate __P((void));
static int ciequal __P((const char * ap, const char * bp));
static void convert __P((long val, char * buf));
static void dolink __P((const char * fromfile, const char * tofile));
static void eat __P((const char * name, int num));
static void eats __P((const char * name, int num,
const char * rname, int rnum));
static long eitol __P((int i));
static void error __P((const char * message));
static char ** getfields __P((char * buf));
static long gethms __P((char * string, const char * errstrng,
int signable));
static void infile __P((const char * filename));
static void inleap __P((char ** fields, int nfields));
static void inlink __P((char ** fields, int nfields));
static void inrule __P((char ** fields, int nfields));
static int inzcont __P((char ** fields, int nfields));
static int inzone __P((char ** fields, int nfields));
static int inzsub __P((char ** fields, int nfields, int iscont));
static int itsabbr __P((const char * abbr, const char * word));
static int itsdir __P((const char * name));
static int lowerit __P((int c));
static char * memcheck __P((char * tocheck));
static int mkdirs __P((char * filename));
static void newabbr __P((const char * abbr));
static long oadd __P((long t1, long t2));
static void outzone __P((const struct zone * zp, int ntzones));
static void puttzcode __P((long code, FILE * fp));
static int rcomp __P((const void *leftp, const void *rightp));
static time_t rpytime __P((const struct rule * rp, int wantedy));
static void rulesub __P((struct rule * rp, char * loyearp, char * hiyearp,
char * typep, char * monthp, char * dayp, char * timep));
static void setboundaries __P((void));
static time_t tadd __P((time_t t1, long t2));
static void usage __P((void));
static void writezone __P((const char * name));
static int yearistype __P((int year, const char * type));
static int charcnt;
static int errors;
static const char * filename;
static int leapcnt;
static int linenum;
static time_t max_time;
static int max_year;
static time_t min_time;
static int min_year;
static int noise;
static const char * rfilename;
static int rlinenum;
static const char * progname;
static int timecnt;
static int typecnt;
static int tt_signed;
/*
** Line codes.
*/
#define LC_RULE 0
#define LC_ZONE 1
#define LC_LINK 2
#define LC_LEAP 3
/*
** Which fields are which on a Zone line.
*/
#define ZF_NAME 1
#define ZF_GMTOFF 2
#define ZF_RULE 3
#define ZF_FORMAT 4
#define ZF_TILYEAR 5
#define ZF_TILMONTH 6
#define ZF_TILDAY 7
#define ZF_TILTIME 8
#define ZONE_MINFIELDS 5
#define ZONE_MAXFIELDS 9
/*
** Which fields are which on a Zone continuation line.
*/
#define ZFC_GMTOFF 0
#define ZFC_RULE 1
#define ZFC_FORMAT 2
#define ZFC_TILYEAR 3
#define ZFC_TILMONTH 4
#define ZFC_TILDAY 5
#define ZFC_TILTIME 6
#define ZONEC_MINFIELDS 3
#define ZONEC_MAXFIELDS 7
/*
** Which files are which on a Rule line.
*/
#define RF_NAME 1
#define RF_LOYEAR 2
#define RF_HIYEAR 3
#define RF_COMMAND 4
#define RF_MONTH 5
#define RF_DAY 6
#define RF_TOD 7
#define RF_STDOFF 8
#define RF_ABBRVAR 9
#define RULE_FIELDS 10
/*
** Which fields are which on a Link line.
*/
#define LF_FROM 1
#define LF_TO 2
#define LINK_FIELDS 3
/*
** Which fields are which on a Leap line.
*/
#define LP_YEAR 1
#define LP_MONTH 2
#define LP_DAY 3
#define LP_TIME 4
#define LP_CORR 5
#define LP_ROLL 6
#define LEAP_FIELDS 7
/*
** Year synonyms.
*/
#define YR_MINIMUM 0
#define YR_MAXIMUM 1
#define YR_ONLY 2
static struct rule * rules;
static int nrules; /* number of rules */
static struct zone * zones;
static int nzones; /* number of zones */
struct link {
const char * l_filename;
int l_linenum;
const char * l_from;
const char * l_to;
};
static struct link * links;
static int nlinks;
struct lookup {
const char * l_word;
const int l_value;
};
static struct lookup const * byword __P((const char * string,
const struct lookup * lp));
static struct lookup const line_codes[] = {
"Rule", LC_RULE,
"Zone", LC_ZONE,
"Link", LC_LINK,
"Leap", LC_LEAP,
NULL, 0
};
static struct lookup const mon_names[] = {
"January", TM_JANUARY,
"February", TM_FEBRUARY,
"March", TM_MARCH,
"April", TM_APRIL,
"May", TM_MAY,
"June", TM_JUNE,
"July", TM_JULY,
"August", TM_AUGUST,
"September", TM_SEPTEMBER,
"October", TM_OCTOBER,
"November", TM_NOVEMBER,
"December", TM_DECEMBER,
NULL, 0
};
static struct lookup const wday_names[] = {
"Sunday", TM_SUNDAY,
"Monday", TM_MONDAY,
"Tuesday", TM_TUESDAY,
"Wednesday", TM_WEDNESDAY,
"Thursday", TM_THURSDAY,
"Friday", TM_FRIDAY,
"Saturday", TM_SATURDAY,
NULL, 0
};
static struct lookup const lasts[] = {
"last-Sunday", TM_SUNDAY,
"last-Monday", TM_MONDAY,
"last-Tuesday", TM_TUESDAY,
"last-Wednesday", TM_WEDNESDAY,
"last-Thursday", TM_THURSDAY,
"last-Friday", TM_FRIDAY,
"last-Saturday", TM_SATURDAY,
NULL, 0
};
static struct lookup const begin_years[] = {
"minimum", YR_MINIMUM,
"maximum", YR_MAXIMUM,
NULL, 0
};
static struct lookup const end_years[] = {
"minimum", YR_MINIMUM,
"maximum", YR_MAXIMUM,
"only", YR_ONLY,
NULL, 0
};
static struct lookup const leap_types[] = {
"Rolling", TRUE,
"Stationary", FALSE,
NULL, 0
};
static const int len_months[2][MONSPERYEAR] = {
31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31,
31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31
};
static const int len_years[2] = {
DAYSPERNYEAR, DAYSPERLYEAR
};
static time_t ats[TZ_MAX_TIMES];
static unsigned char types[TZ_MAX_TIMES];
static long gmtoffs[TZ_MAX_TYPES];
static char isdsts[TZ_MAX_TYPES];
static char abbrinds[TZ_MAX_TYPES];
static char ttisstds[TZ_MAX_TYPES];
static char chars[TZ_MAX_CHARS];
static time_t trans[TZ_MAX_LEAPS];
static long corr[TZ_MAX_LEAPS];
static char roll[TZ_MAX_LEAPS];
/*
** Memory allocation.
*/
static char *
memcheck(ptr)
char * const ptr;
{
if (ptr == NULL) {
(void) perror(progname);
(void) exit(EXIT_FAILURE);
}
return ptr;
}
#define emalloc(size) memcheck(imalloc(size))
#define erealloc(ptr, size) memcheck(irealloc(ptr, size))
#define ecpyalloc(ptr) memcheck(icpyalloc(ptr))
#define ecatalloc(oldp, newp) memcheck(icatalloc(oldp, newp))
/*
** Error handling.
*/
static void
eats(name, num, rname, rnum)
const char * const name;
const int num;
const char * const rname;
const int rnum;
{
filename = name;
linenum = num;
rfilename = rname;
rlinenum = rnum;
}
static void
eat(name, num)
const char * const name;
const int num;
{
eats(name, num, (char *) NULL, -1);
}
static void
error(string)
const char * const string;
{
/*
** Match the format of "cc" to allow sh users to
** zic ... 2>&1 | error -t "*" -v
** on BSD systems.
*/
(void) fprintf(stderr, "\"%s\", line %d: %s",
filename, linenum, string);
if (rfilename != NULL)
(void) fprintf(stderr, " (rule from \"%s\", line %d)",
rfilename, rlinenum);
(void) fprintf(stderr, "\n");
++errors;
}
static void
usage()
{
(void) fprintf(stderr,
"%s: usage is %s [ -s ] [ -v ] [ -l localtime ] [ -p posixrules ] [ -d directory ]\n\
\t[ -L leapseconds ] [ filename ... ]\n",
progname, progname);
(void) exit(EXIT_FAILURE);
}
static const char * psxrules = NULL;
static const char * lcltime = NULL;
static const char * directory = NULL;
static const char * leapsec = NULL;
static int sflag = FALSE;
int
main(argc, argv)
int argc;
char * argv[];
{
register int i, j;
register int c;
(void) umask(umask(022) | 022);
progname = argv[0];
while ((c = getopt(argc, argv, "d:l:p:L:vs")) != EOF)
switch (c) {
default:
usage();
case 'd':
if (directory == NULL)
directory = optarg;
else {
(void) fprintf(stderr,
"%s: More than one -d option specified\n",
progname);
(void) exit(EXIT_FAILURE);
}
break;
case 'l':
if (lcltime == NULL)
lcltime = optarg;
else {
(void) fprintf(stderr,
"%s: More than one -l option specified\n",
progname);
(void) exit(EXIT_FAILURE);
}
break;
case 'p':
if (psxrules == NULL)
psxrules = optarg;
else {
(void) fprintf(stderr,
"%s: More than one -p option specified\n",
progname);
(void) exit(EXIT_FAILURE);
}
break;
case 'L':
if (leapsec == NULL)
leapsec = optarg;
else {
(void) fprintf(stderr,
"%s: More than one -L option specified\n",
progname);
(void) exit(EXIT_FAILURE);
}
break;
case 'v':
noise = TRUE;
break;
case 's':
sflag = TRUE;
break;
}
if (optind == argc - 1 && strcmp(argv[optind], "=") == 0)
usage(); /* usage message by request */
if (directory == NULL)
directory = TZDIR;
setboundaries();
if (optind < argc && leapsec != NULL) {
infile(leapsec);
adjleap();
}
zones = (struct zone *) emalloc(0);
rules = (struct rule *) emalloc(0);
links = (struct link *) emalloc(0);
for (i = optind; i < argc; ++i)
infile(argv[i]);
if (errors)
(void) exit(EXIT_FAILURE);
associate();
for (i = 0; i < nzones; i = j) {
/*
** Find the next non-continuation zone entry.
*/
for (j = i + 1; j < nzones && zones[j].z_name == NULL; ++j)
;
outzone(&zones[i], j - i);
}
/*
** Make links.
*/
for (i = 0; i < nlinks; ++i)
dolink(links[i].l_from, links[i].l_to);
if (lcltime != NULL)
dolink(lcltime, TZDEFAULT);
if (psxrules != NULL)
dolink(psxrules, TZDEFRULES);
return (errors == 0) ? EXIT_SUCCESS : EXIT_FAILURE;
}
static void
dolink(fromfile, tofile)
const char * const fromfile;
const char * const tofile;
{
register char * fromname;
register char * toname;
fromname = ecpyalloc(directory);
fromname = ecatalloc(fromname, "/");
fromname = ecatalloc(fromname, fromfile);
toname = ecpyalloc(directory);
toname = ecatalloc(toname, "/");
toname = ecatalloc(toname, tofile);
/*
** We get to be careful here since
** there's a fair chance of root running us.
*/
if (!itsdir(toname))
(void) remove(toname);
if (link(fromname, toname) != 0) {
(void) fprintf(stderr, "%s: Can't link from %s to ",
progname, fromname);
(void) perror(toname);
(void) exit(EXIT_FAILURE);
}
ifree(fromname);
ifree(toname);
}
static void
setboundaries()
{
register time_t bit;
for (bit = 1; bit > 0; bit <<= 1)
;
if (bit == 0) { /* time_t is an unsigned type */
tt_signed = FALSE;
min_time = 0;
max_time = ~(time_t) 0;
if (sflag)
max_time >>= 1;
} else {
tt_signed = TRUE;
min_time = bit;
max_time = bit;
++max_time;
max_time = -max_time;
if (sflag)
min_time = 0;
}
min_year = TM_YEAR_BASE + gmtime(&min_time)->tm_year;
max_year = TM_YEAR_BASE + gmtime(&max_time)->tm_year;
}
static int
itsdir(name)
const char * const name;
{
struct stat s;
return (stat(name, &s) == 0 && S_ISDIR(s.st_mode));
}
/*
** Associate sets of rules with zones.
*/
/*
** Sort by rule name.
*/
static int
rcomp(cp1, cp2)
const void * cp1;
const void * cp2;
{
return strcmp(((struct rule *) cp1)->r_name,
((struct rule *) cp2)->r_name);
}
static void
associate()
{
register struct zone * zp;
register struct rule * rp;
register int base, out;
register int i;
if (nrules != 0)
(void) qsort((void *) rules, (size_t) nrules,
(size_t) sizeof *rules, rcomp);
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
zp->z_rules = NULL;
zp->z_nrules = 0;
}
for (base = 0; base < nrules; base = out) {
rp = &rules[base];
for (out = base + 1; out < nrules; ++out)
if (strcmp(rp->r_name, rules[out].r_name) != 0)
break;
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
if (strcmp(zp->z_rule, rp->r_name) != 0)
continue;
zp->z_rules = rp;
zp->z_nrules = out - base;
}
}
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
if (zp->z_nrules == 0) {
/*
** Maybe we have a local standard time offset.
*/
eat(zp->z_filename, zp->z_linenum);
zp->z_stdoff =
gethms((char *)zp->z_rule, "unruly zone", TRUE);
/*
** Note, though, that if there's no rule,
** a '%s' in the format is a bad thing.
*/
if (strchr(zp->z_format, '%') != 0)
error("%s in ruleless zone");
}
}
if (errors)
(void) exit(EXIT_FAILURE);
}
static void
infile(name)
const char * name;
{
register FILE * fp;
register char ** fields;
register char * cp;
register const struct lookup * lp;
register int nfields;
register int wantcont;
register int num;
char buf[BUFSIZ];
if (strcmp(name, "-") == 0) {
name = "standard input";
fp = stdin;
} else if ((fp = fopen(name, "r")) == NULL) {
(void) fprintf(stderr, "%s: Can't open ", progname);
(void) perror(name);
(void) exit(EXIT_FAILURE);
}
wantcont = FALSE;
for (num = 1; ; ++num) {
eat(name, num);
if (fgets(buf, (int) sizeof buf, fp) != buf)
break;
cp = strchr(buf, '\n');
if (cp == NULL) {
error("line too long");
(void) exit(EXIT_FAILURE);
}
*cp = '\0';
fields = getfields(buf);
nfields = 0;
while (fields[nfields] != NULL) {
if (ciequal(fields[nfields], "-"))
fields[nfields] = "";
++nfields;
}
if (nfields == 0) {
/* nothing to do */
} else if (wantcont) {
wantcont = inzcont(fields, nfields);
} else {
lp = byword(fields[0], line_codes);
if (lp == NULL)
error("input line of unknown type");
else switch ((int) (lp->l_value)) {
case LC_RULE:
inrule(fields, nfields);
wantcont = FALSE;
break;
case LC_ZONE:
wantcont = inzone(fields, nfields);
break;
case LC_LINK:
inlink(fields, nfields);
wantcont = FALSE;
break;
case LC_LEAP:
if (name != leapsec)
(void) fprintf(stderr,
"%s: Leap line in non leap seconds file %s\n",
progname, name);
else inleap(fields, nfields);
wantcont = FALSE;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
"%s: panic: Invalid l_value %d\n",
progname, lp->l_value);
(void) exit(EXIT_FAILURE);
}
}
ifree((char *) fields);
}
if (ferror(fp)) {
(void) fprintf(stderr, "%s: Error reading ", progname);
(void) perror(filename);
(void) exit(EXIT_FAILURE);
}
if (fp != stdin && fclose(fp)) {
(void) fprintf(stderr, "%s: Error closing ", progname);
(void) perror(filename);
(void) exit(EXIT_FAILURE);
}
if (wantcont)
error("expected continuation line not found");
}
/*
** Convert a string of one of the forms
** h -h hh:mm -hh:mm hh:mm:ss -hh:mm:ss
** into a number of seconds.
** A null string maps to zero.
** Call error with errstring and return zero on errors.
*/
static long
gethms(string, errstring, signable)
char * string;
const char * const errstring;
const int signable;
{
int hh, mm, ss, sign;
if (string == NULL || *string == '\0')
return 0;
if (!signable)
sign = 1;
else if (*string == '-') {
sign = -1;
++string;
} else sign = 1;
if (sscanf(string, scheck(string, "%d"), &hh) == 1)
mm = ss = 0;
else if (sscanf(string, scheck(string, "%d:%d"), &hh, &mm) == 2)
ss = 0;
else if (sscanf(string, scheck(string, "%d:%d:%d"),
&hh, &mm, &ss) != 3) {
error(errstring);
return 0;
}
if (hh < 0 || hh >= HOURSPERDAY ||
mm < 0 || mm >= MINSPERHOUR ||
ss < 0 || ss > SECSPERMIN) {
error(errstring);
return 0;
}
return eitol(sign) *
(eitol(hh * MINSPERHOUR + mm) *
eitol(SECSPERMIN) + eitol(ss));
}
static void
inrule(fields, nfields)
register char ** const fields;
const int nfields;
{
static struct rule r;
if (nfields != RULE_FIELDS) {
error("wrong number of fields on Rule line");
return;
}
if (*fields[RF_NAME] == '\0') {
error("nameless rule");
return;
}
r.r_filename = filename;
r.r_linenum = linenum;
r.r_stdoff = gethms(fields[RF_STDOFF], "invalid saved time", TRUE);
rulesub(&r, fields[RF_LOYEAR], fields[RF_HIYEAR], fields[RF_COMMAND],
fields[RF_MONTH], fields[RF_DAY], fields[RF_TOD]);
r.r_name = ecpyalloc(fields[RF_NAME]);
r.r_abbrvar = ecpyalloc(fields[RF_ABBRVAR]);
rules = (struct rule *) erealloc((char *) rules,
(int) ((nrules + 1) * sizeof *rules));
rules[nrules++] = r;
}
static int
inzone(fields, nfields)
register char ** const fields;
const int nfields;
{
register int i;
char buf[132];
if (nfields < ZONE_MINFIELDS || nfields > ZONE_MAXFIELDS) {
error("wrong number of fields on Zone line");
return FALSE;
}
if (strcmp(fields[ZF_NAME], TZDEFAULT) == 0 && lcltime != NULL) {
(void) sprintf(buf,
"\"Zone %s\" line and -l option are mutually exclusive",
TZDEFAULT);
error(buf);
return FALSE;
}
if (strcmp(fields[ZF_NAME], TZDEFRULES) == 0 && psxrules != NULL) {
(void) sprintf(buf,
"\"Zone %s\" line and -p option are mutually exclusive",
TZDEFRULES);
error(buf);
return FALSE;
}
for (i = 0; i < nzones; ++i)
if (zones[i].z_name != NULL &&
strcmp(zones[i].z_name, fields[ZF_NAME]) == 0) {
(void) sprintf(buf,
"duplicate zone name %s (file \"%s\", line %d)",
fields[ZF_NAME],
zones[i].z_filename,
zones[i].z_linenum);
error(buf);
return FALSE;
}
return inzsub(fields, nfields, FALSE);
}
static int
inzcont(fields, nfields)
register char ** const fields;
const int nfields;
{
if (nfields < ZONEC_MINFIELDS || nfields > ZONEC_MAXFIELDS) {
error("wrong number of fields on Zone continuation line");
return FALSE;
}
return inzsub(fields, nfields, TRUE);
}
static int
inzsub(fields, nfields, iscont)
register char ** const fields;
const int nfields;
const int iscont;
{
register char * cp;
static struct zone z;
register int i_gmtoff, i_rule, i_format;
register int i_untilyear, i_untilmonth;
register int i_untilday, i_untiltime;
register int hasuntil;
if (iscont) {
i_gmtoff = ZFC_GMTOFF;
i_rule = ZFC_RULE;
i_format = ZFC_FORMAT;
i_untilyear = ZFC_TILYEAR;
i_untilmonth = ZFC_TILMONTH;
i_untilday = ZFC_TILDAY;
i_untiltime = ZFC_TILTIME;
z.z_name = NULL;
} else {
i_gmtoff = ZF_GMTOFF;
i_rule = ZF_RULE;
i_format = ZF_FORMAT;
i_untilyear = ZF_TILYEAR;
i_untilmonth = ZF_TILMONTH;
i_untilday = ZF_TILDAY;
i_untiltime = ZF_TILTIME;
z.z_name = ecpyalloc(fields[ZF_NAME]);
}
z.z_filename = filename;
z.z_linenum = linenum;
z.z_gmtoff = gethms(fields[i_gmtoff], "invalid GMT offset", TRUE);
if ((cp = strchr(fields[i_format], '%')) != 0) {
if (*++cp != 's' || strchr(cp, '%') != 0) {
error("invalid abbreviation format");
return FALSE;
}
}
z.z_rule = ecpyalloc(fields[i_rule]);
z.z_format = ecpyalloc(fields[i_format]);
hasuntil = nfields > i_untilyear;
if (hasuntil) {
z.z_untilrule.r_filename = filename;
z.z_untilrule.r_linenum = linenum;
rulesub(&z.z_untilrule,
fields[i_untilyear],
"only",
"",
(nfields > i_untilmonth) ? fields[i_untilmonth] : "Jan",
(nfields > i_untilday) ? fields[i_untilday] : "1",
(nfields > i_untiltime) ? fields[i_untiltime] : "0");
z.z_untiltime = rpytime(&z.z_untilrule, z.z_untilrule.r_loyear);
if (iscont && nzones > 0 && z.z_untiltime < max_time &&
z.z_untiltime > min_time &&
zones[nzones - 1].z_untiltime >= z.z_untiltime) {
error("Zone continuation line end time is not after end time of previous line");
return FALSE;
}
}
zones = (struct zone *) erealloc((char *) zones,
(int) ((nzones + 1) * sizeof *zones));
zones[nzones++] = z;
/*
** If there was an UNTIL field on this line,
** there's more information about the zone on the next line.
*/
return hasuntil;
}
static void
inleap(fields, nfields)
register char ** const fields;
const int nfields;
{
register const char * cp;
register const struct lookup * lp;
register int i, j;
int year, month, day;
long dayoff, tod;
time_t t;
if (nfields != LEAP_FIELDS) {
error("wrong number of fields on Leap line");
return;
}
dayoff = 0;
cp = fields[LP_YEAR];
if (sscanf((char *)cp, scheck(cp, "%d"), &year) != 1 ||
year < min_year || year > max_year) {
/*
* Leapin' Lizards!
*/
error("invalid leaping year");
return;
}
j = EPOCH_YEAR;
while (j != year) {
if (year > j) {
i = len_years[isleap(j)];
++j;
} else {
--j;
i = -len_years[isleap(j)];
}
dayoff = oadd(dayoff, eitol(i));
}
if ((lp = byword(fields[LP_MONTH], mon_names)) == NULL) {
error("invalid month name");
return;
}
month = lp->l_value;
j = TM_JANUARY;
while (j != month) {
i = len_months[isleap(year)][j];
dayoff = oadd(dayoff, eitol(i));
++j;
}
cp = fields[LP_DAY];
if (sscanf((char *)cp, scheck(cp, "%d"), &day) != 1 ||
day <= 0 || day > len_months[isleap(year)][month]) {
error("invalid day of month");
return;
}
dayoff = oadd(dayoff, eitol(day - 1));
if (dayoff < 0 && !tt_signed) {
error("time before zero");
return;
}
t = (time_t) dayoff * SECSPERDAY;
/*
** Cheap overflow check.
*/
if (t / SECSPERDAY != dayoff) {
error("time overflow");
return;
}
tod = gethms(fields[LP_TIME], "invalid time of day", FALSE);
cp = fields[LP_CORR];
if (strcmp(cp, "+") != 0 && strcmp(cp, "") != 0) {
/* infile() turned "-" into "" */
error("illegal CORRECTION field on Leap line");
return;
}
if ((lp = byword(fields[LP_ROLL], leap_types)) == NULL) {
error("illegal Rolling/Stationary field on Leap line");
return;
}
addleap(tadd(t, tod), *cp == '+', lp->l_value);
}
static void
inlink(fields, nfields)
register char ** const fields;
const int nfields;
{
struct link l;
if (nfields != LINK_FIELDS) {
error("wrong number of fields on Link line");
return;
}
if (*fields[LF_FROM] == '\0') {
error("blank FROM field on Link line");
return;
}
if (*fields[LF_TO] == '\0') {
error("blank TO field on Link line");
return;
}
l.l_filename = filename;
l.l_linenum = linenum;
l.l_from = ecpyalloc(fields[LF_FROM]);
l.l_to = ecpyalloc(fields[LF_TO]);
links = (struct link *) erealloc((char *) links,
(int) ((nlinks + 1) * sizeof *links));
links[nlinks++] = l;
}
static void
rulesub(rp, loyearp, hiyearp, typep, monthp, dayp, timep)
register struct rule * const rp;
char * const loyearp;
char * const hiyearp;
char * const typep;
char * const monthp;
char * const dayp;
char * const timep;
{
register struct lookup const * lp;
register char * cp;
if ((lp = byword(monthp, mon_names)) == NULL) {
error("invalid month name");
return;
}
rp->r_month = lp->l_value;
rp->r_todisstd = FALSE;
cp = timep;
if (*cp != '\0') {
cp += strlen(cp) - 1;
switch (lowerit(*cp)) {
case 's':
rp->r_todisstd = TRUE;
*cp = '\0';
break;
case 'w':
rp->r_todisstd = FALSE;
*cp = '\0';
break;
}
}
rp->r_tod = gethms(timep, "invalid time of day", FALSE);
/*
** Year work.
*/
cp = loyearp;
if ((lp = byword(cp, begin_years)) != NULL) switch ((int) lp->l_value) {
case YR_MINIMUM:
rp->r_loyear = min_year;
break;
case YR_MAXIMUM:
rp->r_loyear = max_year;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
"%s: panic: Invalid l_value %d\n",
progname, lp->l_value);
(void) exit(EXIT_FAILURE);
} else if (sscanf(cp, scheck(cp, "%d"), &rp->r_loyear) != 1 ||
rp->r_loyear < min_year || rp->r_loyear > max_year) {
if (noise)
error("invalid starting year");
if (rp->r_loyear > max_year)
return;
}
cp = hiyearp;
if ((lp = byword(cp, end_years)) != NULL) switch ((int) lp->l_value) {
case YR_MINIMUM:
rp->r_hiyear = min_year;
break;
case YR_MAXIMUM:
rp->r_hiyear = max_year;
break;
case YR_ONLY:
rp->r_hiyear = rp->r_loyear;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
"%s: panic: Invalid l_value %d\n",
progname, lp->l_value);
(void) exit(EXIT_FAILURE);
} else if (sscanf(cp, scheck(cp, "%d"), &rp->r_hiyear) != 1 ||
rp->r_hiyear < min_year || rp->r_hiyear > max_year) {
if (noise)
error("invalid ending year");
if (rp->r_hiyear < min_year)
return;
}
if (rp->r_hiyear < min_year)
return;
if (rp->r_loyear < min_year)
rp->r_loyear = min_year;
if (rp->r_hiyear > max_year)
rp->r_hiyear = max_year;
if (rp->r_loyear > rp->r_hiyear) {
error("starting year greater than ending year");
return;
}
if (*typep == '\0')
rp->r_yrtype = NULL;
else {
if (rp->r_loyear == rp->r_hiyear) {
error("typed single year");
return;
}
rp->r_yrtype = ecpyalloc(typep);
}
/*
** Day work.
** Accept things such as:
** 1
** last-Sunday
** Sun<=20
** Sun>=7
*/
if ((lp = byword(dayp, lasts)) != NULL) {
rp->r_dycode = DC_DOWLEQ;
rp->r_wday = lp->l_value;
rp->r_dayofmonth = len_months[1][rp->r_month];
} else {
if ((cp = strchr(dayp, '<')) != 0)
rp->r_dycode = DC_DOWLEQ;
else if ((cp = strchr(dayp, '>')) != 0)
rp->r_dycode = DC_DOWGEQ;
else {
cp = dayp;
rp->r_dycode = DC_DOM;
}
if (rp->r_dycode != DC_DOM) {
*cp++ = 0;
if (*cp++ != '=') {
error("invalid day of month");
return;
}
if ((lp = byword(dayp, wday_names)) == NULL) {
error("invalid weekday name");
return;
}
rp->r_wday = lp->l_value;
}
if (sscanf(cp, scheck(cp, "%d"), &rp->r_dayofmonth) != 1 ||
rp->r_dayofmonth <= 0 ||
(rp->r_dayofmonth > len_months[1][rp->r_month])) {
error("invalid day of month");
return;
}
}
}
static void
convert(val, buf)
const long val;
char * const buf;
{
register int i;
register long shift;
for (i = 0, shift = 24; i < 4; ++i, shift -= 8)
buf[i] = val >> shift;
}
static void
puttzcode(val, fp)
const long val;
FILE * const fp;
{
char buf[4];
convert(val, buf);
(void) fwrite((void *) buf, (size_t) sizeof buf, (size_t) 1, fp);
}
static void
writezone(name)
const char * const name;
{
register FILE * fp;
register int i, j;
char fullname[BUFSIZ];
static struct tzhead tzh;
if (strlen(directory) + 1 + strlen(name) >= sizeof fullname) {
(void) fprintf(stderr,
"%s: File name %s/%s too long\n", progname,
directory, name);
(void) exit(EXIT_FAILURE);
}
(void) sprintf(fullname, "%s/%s", directory, name);
if ((fp = fopen(fullname, "wb")) == NULL) {
if (mkdirs(fullname) != 0)
(void) exit(EXIT_FAILURE);
if ((fp = fopen(fullname, "wb")) == NULL) {
(void) fprintf(stderr, "%s: Can't create ", progname);
(void) perror(fullname);
(void) exit(EXIT_FAILURE);
}
}
convert(eitol(typecnt), tzh.tzh_ttisstdcnt);
convert(eitol(leapcnt), tzh.tzh_leapcnt);
convert(eitol(timecnt), tzh.tzh_timecnt);
convert(eitol(typecnt), tzh.tzh_typecnt);
convert(eitol(charcnt), tzh.tzh_charcnt);
(void) fwrite((void *) &tzh, (size_t) sizeof tzh, (size_t) 1, fp);
for (i = 0; i < timecnt; ++i) {
j = leapcnt;
while (--j >= 0)
if (ats[i] >= trans[j]) {
ats[i] = tadd(ats[i], corr[j]);
break;
}
puttzcode((long) ats[i], fp);
}
if (timecnt > 0)
(void) fwrite((void *) types, (size_t) sizeof types[0],
(size_t) timecnt, fp);
for (i = 0; i < typecnt; ++i) {
puttzcode((long) gmtoffs[i], fp);
(void) putc(isdsts[i], fp);
(void) putc(abbrinds[i], fp);
}
if (charcnt != 0)
(void) fwrite((void *) chars, (size_t) sizeof chars[0],
(size_t) charcnt, fp);
for (i = 0; i < leapcnt; ++i) {
if (roll[i]) {
if (timecnt == 0 || trans[i] < ats[0]) {
j = 0;
while (isdsts[j])
if (++j >= typecnt) {
j = 0;
break;
}
} else {
j = 1;
while (j < timecnt && trans[i] >= ats[j])
++j;
j = types[j - 1];
}
puttzcode((long) tadd(trans[i], -gmtoffs[j]), fp);
} else puttzcode((long) trans[i], fp);
puttzcode((long) corr[i], fp);
}
for (i = 0; i < typecnt; ++i)
(void) putc(ttisstds[i], fp);
if (ferror(fp) || fclose(fp)) {
(void) fprintf(stderr, "%s: Write error on ", progname);
(void) perror(fullname);
(void) exit(EXIT_FAILURE);
}
}
static void
outzone(zpfirst, zonecount)
const struct zone * const zpfirst;
const int zonecount;
{
register const struct zone * zp;
register struct rule * rp;
register int i, j;
register int usestart, useuntil;
register time_t starttime, untiltime;
register long gmtoff;
register long stdoff;
register int year;
register long startoff;
register int startisdst;
register int startttisstd;
register int type;
char startbuf[BUFSIZ];
/*
** Now. . .finally. . .generate some useful data!
*/
timecnt = 0;
typecnt = 0;
charcnt = 0;
/*
** Two guesses. . .the second may well be corrected later.
*/
gmtoff = zpfirst->z_gmtoff;
stdoff = 0;
starttime = 0;
startttisstd = FALSE;
for (i = 0; i < zonecount; ++i) {
usestart = i > 0;
useuntil = i < (zonecount - 1);
zp = &zpfirst[i];
eat(zp->z_filename, zp->z_linenum);
startisdst = -1;
if (zp->z_nrules == 0) {
type = addtype(oadd(zp->z_gmtoff, zp->z_stdoff),
zp->z_format, zp->z_stdoff != 0,
startttisstd);
if (usestart)
addtt(starttime, type);
gmtoff = zp->z_gmtoff;
stdoff = zp->z_stdoff;
} else for (year = min_year; year <= max_year; ++year) {
if (useuntil && year > zp->z_untilrule.r_hiyear)
break;
/*
** Mark which rules to do in the current year.
** For those to do, calculate rpytime(rp, year);
*/
for (j = 0; j < zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
rp->r_todo = year >= rp->r_loyear &&
year <= rp->r_hiyear &&
yearistype(year, rp->r_yrtype);
if (rp->r_todo)
rp->r_temp = rpytime(rp, year);
}
for ( ; ; ) {
register int k;
register time_t jtime, ktime;
register long offset;
char buf[BUFSIZ];
if (useuntil) {
/*
** Turn untiltime into GMT
** assuming the current gmtoff and
** stdoff values.
*/
offset = gmtoff;
if (!zp->z_untilrule.r_todisstd)
offset = oadd(offset, stdoff);
untiltime = tadd(zp->z_untiltime,
-offset);
}
/*
** Find the rule (of those to do, if any)
** that takes effect earliest in the year.
*/
k = -1;
#ifdef lint
ktime = 0;
#endif /* defined lint */
for (j = 0; j < zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
if (!rp->r_todo)
continue;
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
offset = gmtoff;
if (!rp->r_todisstd)
offset = oadd(offset, stdoff);
jtime = rp->r_temp;
if (jtime == min_time ||
jtime == max_time)
continue;
jtime = tadd(jtime, -offset);
if (k < 0 || jtime < ktime) {
k = j;
ktime = jtime;
}
}
if (k < 0)
break; /* go on to next year */
rp = &zp->z_rules[k];
rp->r_todo = FALSE;
if (useuntil && ktime >= untiltime)
break;
if (usestart) {
if (ktime < starttime) {
stdoff = rp->r_stdoff;
startoff = oadd(zp->z_gmtoff,
rp->r_stdoff);
(void) sprintf(startbuf,
zp->z_format,
rp->r_abbrvar);
startisdst =
rp->r_stdoff != 0;
continue;
}
if (ktime != starttime &&
startisdst >= 0)
addtt(starttime, addtype(startoff, startbuf, startisdst, startttisstd));
usestart = FALSE;
}
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
(void) sprintf(buf, zp->z_format,
rp->r_abbrvar);
offset = oadd(zp->z_gmtoff, rp->r_stdoff);
type = addtype(offset, buf, rp->r_stdoff != 0,
rp->r_todisstd);
if (timecnt != 0 || rp->r_stdoff != 0)
addtt(ktime, type);
gmtoff = zp->z_gmtoff;
stdoff = rp->r_stdoff;
}
}
/*
** Now we may get to set starttime for the next zone line.
*/
if (useuntil) {
starttime = tadd(zp->z_untiltime,
-gmtoffs[types[timecnt - 1]]);
startttisstd = zp->z_untilrule.r_todisstd;
}
}
writezone(zpfirst->z_name);
}
static void
addtt(starttime, type)
const time_t starttime;
const int type;
{
if (timecnt != 0 && type == types[timecnt - 1])
return; /* easy enough! */
if (timecnt >= TZ_MAX_TIMES) {
error("too many transitions?!");
(void) exit(EXIT_FAILURE);
}
ats[timecnt] = starttime;
types[timecnt] = type;
++timecnt;
}
static int
addtype(gmtoff, abbr, isdst, ttisstd)
const long gmtoff;
const char * const abbr;
const int isdst;
const int ttisstd;
{
register int i, j;
/*
** See if there's already an entry for this zone type.
** If so, just return its index.
*/
for (i = 0; i < typecnt; ++i) {
if (gmtoff == gmtoffs[i] && isdst == isdsts[i] &&
strcmp(abbr, &chars[abbrinds[i]]) == 0 &&
ttisstd == ttisstds[i])
return i;
}
/*
** There isn't one; add a new one, unless there are already too
** many.
*/
if (typecnt >= TZ_MAX_TYPES) {
error("too many local time types");
(void) exit(EXIT_FAILURE);
}
gmtoffs[i] = gmtoff;
isdsts[i] = isdst;
ttisstds[i] = ttisstd;
for (j = 0; j < charcnt; ++j)
if (strcmp(&chars[j], abbr) == 0)
break;
if (j == charcnt)
newabbr(abbr);
abbrinds[i] = j;
++typecnt;
return i;
}
static void
addleap(t, positive, rolling)
const time_t t;
const int positive;
const int rolling;
{
register int i, j;
if (leapcnt >= TZ_MAX_LEAPS) {
error("too many leap seconds");
(void) exit(EXIT_FAILURE);
}
for (i = 0; i < leapcnt; ++i)
if (t <= trans[i]) {
if (t == trans[i]) {
error("repeated leap second moment");
(void) exit(EXIT_FAILURE);
}
break;
}
for (j = leapcnt; j > i; --j) {
trans[j] = trans[j-1];
corr[j] = corr[j-1];
roll[j] = roll[j-1];
}
trans[i] = t;
corr[i] = (positive ? 1L : -1L);
roll[i] = rolling;
++leapcnt;
}
static void
adjleap()
{
register int i;
register long last = 0;
/*
** propagate leap seconds forward
*/
for (i = 0; i < leapcnt; ++i) {
trans[i] = tadd(trans[i], last);
last = corr[i] += last;
}
}
static int
yearistype(year, type)
const int year;
const char * const type;
{
char buf[BUFSIZ];
int result;
if (type == NULL || *type == '\0')
return TRUE;
if (strcmp(type, "uspres") == 0)
return (year % 4) == 0;
if (strcmp(type, "nonpres") == 0)
return (year % 4) != 0;
(void) sprintf(buf, "yearistype %d %s", year, type);
result = system(buf);
if (result == 0)
return TRUE;
if (result == (1 << 8))
return FALSE;
error("Wild result from command execution");
(void) fprintf(stderr, "%s: command was '%s', result was %d\n",
progname, buf, result);
for ( ; ; )
(void) exit(EXIT_FAILURE);
}
static int
lowerit(a)
const int a;
{
return (isascii(a) && isupper(a)) ? tolower(a) : a;
}
static int
ciequal(ap, bp) /* case-insensitive equality */
register const char * ap;
register const char * bp;
{
while (lowerit(*ap) == lowerit(*bp++))
if (*ap++ == '\0')
return TRUE;
return FALSE;
}
static int
itsabbr(abbr, word)
register const char * abbr;
register const char * word;
{
if (lowerit(*abbr) != lowerit(*word))
return FALSE;
++word;
while (*++abbr != '\0')
do if (*word == '\0')
return FALSE;
while (lowerit(*word++) != lowerit(*abbr));
return TRUE;
}
static const struct lookup *
byword(word, table)
register const char * const word;
register const struct lookup * const table;
{
register const struct lookup * foundlp;
register const struct lookup * lp;
if (word == NULL || table == NULL)
return NULL;
/*
** Look for exact match.
*/
for (lp = table; lp->l_word != NULL; ++lp)
if (ciequal(word, lp->l_word))
return lp;
/*
** Look for inexact match.
*/
foundlp = NULL;
for (lp = table; lp->l_word != NULL; ++lp)
if (itsabbr(word, lp->l_word))
if (foundlp == NULL)
foundlp = lp;
else return NULL; /* multiple inexact matches */
return foundlp;
}
static char **
getfields(cp)
register char * cp;
{
register char * dp;
register char ** array;
register int nsubs;
if (cp == NULL)
return NULL;
array = (char **) emalloc((int) ((strlen(cp) + 1) * sizeof *array));
nsubs = 0;
for ( ; ; ) {
while (isascii(*cp) && isspace(*cp))
++cp;
if (*cp == '\0' || *cp == '#')
break;
array[nsubs++] = dp = cp;
do {
if ((*dp = *cp++) != '"')
++dp;
else while ((*dp = *cp++) != '"')
if (*dp != '\0')
++dp;
else error("Odd number of quotation marks");
} while (*cp != '\0' && *cp != '#' &&
(!isascii(*cp) || !isspace(*cp)));
if (isascii(*cp) && isspace(*cp))
++cp;
*dp = '\0';
}
array[nsubs] = NULL;
return array;
}
static long
oadd(t1, t2)
const long t1;
const long t2;
{
register long t;
t = t1 + t2;
if (t2 > 0 && t <= t1 || t2 < 0 && t >= t1) {
error("time overflow");
(void) exit(EXIT_FAILURE);
}
return t;
}
static time_t
tadd(t1, t2)
const time_t t1;
const long t2;
{
register time_t t;
if (t1 == max_time && t2 > 0)
return max_time;
if (t1 == min_time && t2 < 0)
return min_time;
t = t1 + t2;
if (t2 > 0 && t <= t1 || t2 < 0 && t >= t1) {
error("time overflow");
(void) exit(EXIT_FAILURE);
}
return t;
}
/*
** Given a rule, and a year, compute the date - in seconds since January 1,
** 1970, 00:00 LOCAL time - in that year that the rule refers to.
*/
static time_t
rpytime(rp, wantedy)
register const struct rule * const rp;
register const int wantedy;
{
register int y, m, i;
register long dayoff; /* with a nod to Margaret O. */
register time_t t;
dayoff = 0;
m = TM_JANUARY;
y = EPOCH_YEAR;
while (wantedy != y) {
if (wantedy > y) {
i = len_years[isleap(y)];
++y;
} else {
--y;
i = -len_years[isleap(y)];
}
dayoff = oadd(dayoff, eitol(i));
}
while (m != rp->r_month) {
i = len_months[isleap(y)][m];
dayoff = oadd(dayoff, eitol(i));
++m;
}
i = rp->r_dayofmonth;
if (m == TM_FEBRUARY && i == 29 && !isleap(y)) {
if (rp->r_dycode == DC_DOWLEQ)
--i;
else {
error("use of 2/29 in non leap-year");
(void) exit(EXIT_FAILURE);
}
}
--i;
dayoff = oadd(dayoff, eitol(i));
if (rp->r_dycode == DC_DOWGEQ || rp->r_dycode == DC_DOWLEQ) {
register long wday;
#define LDAYSPERWEEK ((long) DAYSPERWEEK)
wday = eitol(EPOCH_WDAY);
/*
** Don't trust mod of negative numbers.
*/
if (dayoff >= 0)
wday = (wday + dayoff) % LDAYSPERWEEK;
else {
wday -= ((-dayoff) % LDAYSPERWEEK);
if (wday < 0)
wday += LDAYSPERWEEK;
}
while (wday != eitol(rp->r_wday))
if (rp->r_dycode == DC_DOWGEQ) {
dayoff = oadd(dayoff, (long) 1);
if (++wday >= LDAYSPERWEEK)
wday = 0;
++i;
} else {
dayoff = oadd(dayoff, (long) -1);
if (--wday < 0)
wday = LDAYSPERWEEK - 1;
--i;
}
if (i < 0 || i >= len_months[isleap(y)][m]) {
error("no day in month matches rule");
(void) exit(EXIT_FAILURE);
}
}
if (dayoff < 0 && !tt_signed) {
if (wantedy == rp->r_loyear)
return min_time;
error("time before zero");
(void) exit(EXIT_FAILURE);
}
t = (time_t) dayoff * SECSPERDAY;
/*
** Cheap overflow check.
*/
if (t / SECSPERDAY != dayoff) {
if (wantedy == rp->r_hiyear)
return max_time;
if (wantedy == rp->r_loyear)
return min_time;
error("time overflow");
(void) exit(EXIT_FAILURE);
}
return tadd(t, rp->r_tod);
}
static void
newabbr(string)
const char * const string;
{
register int i;
i = strlen(string) + 1;
if (charcnt + i >= TZ_MAX_CHARS) {
error("too many, or too long, time zone abbreviations");
(void) exit(EXIT_FAILURE);
}
(void) strcpy(&chars[charcnt], string);
charcnt += eitol(i);
}
static int
mkdirs(name)
char * const name;
{
register char * cp;
if ((cp = name) == NULL || *cp == '\0')
return 0;
while ((cp = strchr(cp + 1, '/')) != 0) {
*cp = '\0';
if (!itsdir(name)) {
/*
** It doesn't seem to exist, so we try to create it.
*/
if (mkdir(name, 0755) != 0) {
(void) fprintf(stderr,
"%s: Can't create directory ",
progname);
(void) perror(name);
return -1;
}
}
*cp = '/';
}
return 0;
}
static long
eitol(i)
const int i;
{
long l;
l = i;
if (i < 0 && l >= 0 || i == 0 && l != 0 || i > 0 && l <= 0) {
(void) fprintf(stderr, "%s: %d did not sign extend correctly\n",
progname, i);
(void) exit(EXIT_FAILURE);
}
return l;
}
/*
** UNIX is a registered trademark of AT&T.
*/